The fluorophore rhodamine B is often used in biological assays. It is inexpensive, robust under a variety of reaction conditions, can be covalently linked to bioactive molecules, and has suitable spectral properties in terms of absorption and fluorescence wavelength. Nonetheless, there are some drawbacks: it can readily form a spirolactam compound, which is nonfluorescent, and therefore may not be the dye of choice for all fluorescence microscopy applications. Herein this spirolactam formation was observed by purifying such a labeled peptoid with high performance liquid chromatography (HPLC) and monitored in detail by making a series of analytical HPLC runs over time. Additionally, a small library of eight peptoids with rhodamine B as label was synthesized. Analysis of the absorption properties of these molecules demonstrated that the problem of fluorescence loss can be overcome by coupling secondary amines with rhodamine B.
Efficient drug delivery is essential for many therapeutic applications. In this context, Trojan peptoids have attracted attention as powerful tools to deliver bioactive molecules into living cells. Certain cell-penetrating peptides, peptide mimetics, and peptoids have been shown to be endowed with a transport function and the structural features of this function have been characterized. However, most of the research has been done by using mammalian cell cultures as model organisms and the actual cellular mechanism of membrane passage has not been elucidated. Plant cells, which are encased in a cellulosic cell wall and differ in membrane composition, represent an alternative experimental system to address this issue, but so far, have attracted only little attention for both peptide- and peptoid-based carrier systems. Moreover, efficient delivery of nonproteinaceous bioactive macromolecules into living plant cells could complement genetic engineering in biotechnological applications, such as metabolic engineering and molecular farming. In the present study, we investigated carrier peptoids with or without guanidinium side chains with regard to their uptake into plant cells, the cellular mechanism of uptake, and intracellular localization. We can show that in contrast to polyamine peptoids (polylysine-like) fluorescently labeled polyguanidine peptoids (polyarginine-like) enter rapidly into tobacco BY-2 cells without affecting the viability of these cells. A quantitative comparison of this uptake with endocytosis of fluorescently labeled dextranes indicates that the main uptake of the guanidinium peptoids occurs between 30-60 min after the start of incubation and clearly precedes endocytosis. Dual visualization with the endosomal marker FM4-64 shows that the intracellular guanidinium peptoid is distinct from endocytotic vesicles. Once the polyguanidine peptoids have entered the cell, they associate with actin filaments and microtubules. By pharmacological manipulation of the cytoskeleton we tested whether the association with the cytoskeleton is necessary for uptake, and observed that the actin inhibitor latrunculin B as well as the microtubule inhibitor oryzalin impaired uptake and intracellular spread of the guanidinium carrier to a certain extent. These findings are discussed with respect to the potential mechanisms of uptake and with respect to the potential of Trojan peptoids as tools for metabolic engineering in plant biotechnology.
N-substituted glycine oligomers or peptoids with charged side chains are a novel class of cell penetrating peptide mimetics and have been shown to serve as drug delivery agents. Here, we investigated by NMR spectroscopy and quantum chemical calculations whether a Rhodamine B labelled peptoid [RhoB(Spiro)-Ahx]-[But](6A)NH(2) with lysine-like side chains adopts structural motifs similar to regular peptides. Due to a low chemical shift dispersion, high resolution structure determination with conventional NMR-derived distance restraints and J-couplings was not possible. Instead, a combined assignment and structure refinement strategy using the QM/MM force field COSMOS-NMR was developed to interpret the highly ambiguous chemical shift and distance constraints and obtain a medium resolution three-dimensional structural model. This allowed us to select for the all cis-amide conformation of the peptide with a pseudo-helical arrangement of extended side chains as a faithful representative structure of [RhoB(Spiro)-Ahx]-[But](6A)NH(2). We tested the biological activity of the peptoid by live-cell imaging, which showed that the cellular uptake of the peptoid was comparable to conventional cell-penetrating peptides.
Single-molecule microscopy is a powerful tool for investigating various uptake mechanisms of cell-penetrating biomolecules. A particularly interesting class of potential transporter molecules are peptoids. Fluorescence labels for such experiments need to comply with several physical, chemical, and biological requirements. Herein, we report the synthesis and photophysical investigation of new fluorescent pyridinium derived dyes. These fluorescent labels have advantageous structural variations and spacer units in order to avoid undesirable interactions with the labeled molecule and are able to easily functionalize biomolecules. In our case, cell-penetrating peptoids are successfully labeled on solid supports, and in ensemble measurements the photophysical properties of the dyes and the fluorescently labeled peptoids are investigated. Both fluorophores and peptoids are imaged at the single-molecule level in thin polymer gels. With respect to bleaching times and fluorescence lifetimes the dye molecules and the peptoids show only slightly perturbed optical behaviors. These investigations indicate that the new fluorophores fulfill well single-molecule microscopy and solid-phase synthesis requirements.
Abbreviations: BY-2 Nicotiana tabacum L. cv. Bright Yellow 2, CPP cell-permeating peptide, FITC fluorescein isothiocyanate, QDs Fluorescent semiconductor quantum dots Fluorescence microscopy has developed into a key technology of the postgenomic era in biology, because it combines structural information with molecular specificity. However, the resolution of this approach is limited by bleaching and optical cross-reference of the fluorescent labels. Fluorescent semiconductor quantum dots (QDs) provide excellent bleaching stability and tunable emission spectra, and therefore would be an excellent alternative to overcome these limitations. However, to apply them to cell biology, three challenges have to be met: bioconjugation to molecular probes that confer the specificity of the label, passage through the external barriers of the cell, and suppression of toxic side effects of the nanoparticles. In plant cells that are ensheathed by a cellulosic cell wall, these challenges are especially prominent. Moreover, plants are located at the start of the food chain and thus of high relevance for the ecotoxicological assessment of nanomaterials. We have therefore explored the application of nanoparticles to plant cell biology. We have first evaluated different strategies to visualize microtubules by QDs in vitro and in cellula. By using silica-coated QDs coupled to anti-tubulin antibodies we were able to image microtubules in tobacco BY-2 cells by direct immunofluorescence making use of the superior bleaching stability of the nanoparticle label. To adapt this tool for in vivo imaging, we have successfully employed Trojan Peptoids as vehicles into living tobacco cells. We want to extend this strategy not only to use functionalized nanoparticles for life-cell imaging, but also to adapt them as tool to manipulate intracellular architecture.B406
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